Self-motion cues in the natural habitats of zebrafish support lower visual field bias

What is the relationship between retinotopy and object selectivity in human lateral occipital (LO) cortex? We used functional magnetic resonance imaging (fMRI) to examine sensitivity to retinal position and category in LO, an object-selective region positioned posterior to MT along the lateral cortical surface. Six subjects participated in phase-encoded retinotopic mapping experiments as well as block-design experiments in which objects from six different categories were presented at six distinct positions in the visual field. We found substantial position modulation in LO using standard nonobject retinotopic mapping stimuli; this modulation extended beyond the boundaries of visual field maps LO-1 and LO-2. Further, LO showed a pronounced lower visual field bias: more LO voxels represented the lower contralateral visual field, and the mean LO response was higher to objects presented below fixation than above fixation. However, eccentricity effects produced by retinotopic mapping stimuli and objects differed. Whereas LO voxels preferred a range of eccentricities lying mostly outside the fovea in the retinotopic mapping experiment, LO responses were strongest to foveally presented objects. Finally, we found a stronger effect of position than category on both the mean LO response, as well as the distributed response across voxels. Overall these results demonstrate that retinal position exhibits strong effects on neural response in LO and indicates that these position effects may be explained by retinotopic organization.

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Roles of the Retinotopic and Environmental Frames of Reference on Vection

Frontiers in Virtual Reality ◽

10.3389/frvir.2020.581920 ◽

2020 ◽

Vol 1 ◽

Author(s):

Kanon Fujimoto ◽

Hiroshi Ashida

Keyword(s):

Visual Field ◽

Visual Motion ◽

Dominant Role ◽

Visual Fields ◽

Ground Surface ◽

Lower Visual Field ◽

Sitting Posture ◽

Head Mounted Display ◽

Upper Visual Field ◽

Self Motion

Humans perceive self-motion using multisensory information, while vision has a dominant role as is utilized in virtual reality (VR) technologies. Previous studies reported that visual motion presented in the lower visual field (LoVF) induces stronger illusion of self-motion (vection) as compared with the upper visual field (UVF). However, it was still unknown whether the LoVF superiority in vection was based on the retinotopic frame, or rather related to the environmental frame of reference. Here, we investigated the influences of retinotopic and environmental frames on the LoVF superiority of vection. We presented a planer surface along the depth axis in one of four visual fields (upper, lower, right, or left). The texture on the surface moved forward or backward. Participants reported vection while observing the visual stimulus through a VR head mounted display (HMD) in the sitting posture or lateral recumbent position. Results showed that the visual motion induced stronger vection when presented in the LoVF compared with the UVF in both postures. Notably, the vection rating in LoVF was stronger in the sitting than in the recumbent. Moreover, recumbent participants reported stronger vection when the stimulus was presented in the gravitationally lower field than in the gravitationally upper field. These results demonstrate contribution of multiple spatial frames on self-motion perception and imply the importance of ground surface.

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Larger head displacement to optic flow presented in the lower visual field.

10.31234/osf.io/34j7g ◽

2019 ◽

Author(s):

Kanon Fujimoto ◽

Hiroshi Ashida

Keyword(s):

Visual Field ◽

Postural Control ◽

Field Condition ◽

Optic Flow ◽

Postural Adjustment ◽

Lower Visual Field ◽

Postural Response ◽

Head Displacement ◽

Upper Visual Field ◽

Self Motion

Optic flow that simulates self-motion often produces postural adjustment. Although literature suggested that human postural control considerably depends on visual inputs from the lower field in the environment, effects of the vertical location of optic flow are not well investigated on postural response. Here, we examined whether optic flow presented in the lower visual field produces a stronger postural response than optic flow in the upper visual field. Either expanding or contracting the optic flow was presented in three visual locations (upper, lower, and full visual fields) on an Oculus Rift head-mounted display. Head displacement and vection strength was measured. Results showed larger head displacement under the optic flow presentation in the lower visual field, than in the upper visual field, but only for the early period of the presentation of the contracting optic flow. Full visual field condition also produced larger head displacement than the upper visual field condition, but for contraction only. Vection was stronger for the lower visual field than the upper visual field, stronger for full visual field than upper and lower visual field. Our findings support the notion that more ecologically relevant information has a more important role in human postural control and self-motion perception.

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Rotational Self-motion Cues Improve Spatial Learning when Teleporting in Virtual Environments

Symposium on Spatial User Interaction ◽

10.1145/3385959.3418443 ◽

2020 ◽

Author(s):

Alex F. Lim ◽

Jonathan W. Kelly ◽

Nathan C. Sepich ◽

Lucia A. Cherep ◽

Grace C. Freed ◽

...

Keyword(s):

Virtual Environments ◽

Spatial Learning ◽

Motion Cues ◽

Self Motion

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Impacts of Rotation Axis and Frequency on Vestibular Perceptual Thresholds

Multisensory Research ◽

10.1163/22134808-bja10069 ◽

2022 ◽

pp. 1-29

Author(s):

Andrew R. Wagner ◽

Megan J. Kobel ◽

Daniel M. Merfeld

Keyword(s):

Multisensory Integration ◽

Rotation Axis ◽

Semicircular Canals ◽

Rotation Velocity ◽

Pass Filter ◽

Motion Cues ◽

Left Posterior ◽

Rotation Plane ◽

Self Motion ◽

Lower Frequencies

Abstract In an effort to characterize the factors influencing the perception of self-motion rotational cues, vestibular self-motion perceptual thresholds were measured in 14 subjects for rotations in the roll and pitch planes, as well as in the planes aligned with the anatomic orientation of the vertical semicircular canals (i.e., left anterior, right posterior; LARP, and right anterior, left posterior; RALP). To determine the multisensory influence of concurrent otolith cues, within each plane of motion, thresholds were measured at four discrete frequencies for rotations about earth-horizontal (i.e., tilts; EH) and earth-vertical axes (i.e., head positioned in the plane of the rotation; EV). We found that the perception of rotations, stimulating primarily the vertical canals, was consistent with the behavior of a high-pass filter for all planes of motion, with velocity thresholds increasing at lower frequencies of rotation. In contrast, tilt (i.e, EH rotation) velocity thresholds, stimulating both the canals and otoliths (i.e., multisensory integration), decreased at lower frequencies and were significantly lower than earth-vertical rotation thresholds at each frequency below 2 Hz. These data suggest that multisensory integration of otolithic gravity cues with semicircular canal rotation cues enhances perceptual precision for tilt motions at frequencies below 2 Hz. We also showed that rotation thresholds, at least partially, were dependent on the orientation of the rotation plane relative to the anatomical alignment of the vertical canals. Collectively these data provide the first comprehensive report of how frequency and axis of rotation influence perception of rotational self-motion cues stimulating the vertical canals.

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Systematic spatial patterns of the sense of familiarity: Hierarchical modelling based on eye-tracking experiments

Quarterly Journal of Experimental Psychology ◽

10.1177/1747021818781709 ◽

2018 ◽

Vol 72 (4) ◽

pp. 832-846

Author(s):

Kiyofumi Miyoshi ◽

Hiroshi Ashida

Keyword(s):

Working Memory ◽

Visual Field ◽

Spatial Patterns ◽

Stimulus Type ◽

Spatial Configuration ◽

Long Term Memory ◽

Lower Visual Field ◽

Referential Process ◽

Memory Theory ◽

Spatial Configurations

Using different types of stimuli, such as pictures, horizontally written Japanese words, and vertically written Japanese words, this study investigated the spatial patterns of the sense of familiarity within the visual field. The perceptual asymmetry theory predicted that stimuli in the lower visual field would be processed more fluently and would therefore be perceived as more familiar. The working memory theory, originally proposed in space–number research, envisaged type-specific spatial patterns for different stimuli. Participants made old/new recognition memory judgements for stimuli, presented at random positions, while their eye movements were recorded. The observed spatial patterns changed according to the stimulus type (e.g., “more left = older” for horizontally written words and “upper = older” for vertically written words), and this flexibility is encapsulated by the working memory theory as follows: (a) stimulus-type-specific spatial configurations are encoded in long-term memory on the basis of one’s experience (e.g., vertically written words are empirically associated with the “upper = older” spatial configuration), (b) the presentation of a stimulus automatically cues the temporal activation of the associated spatial configuration in working memory, and (c) the referential process between the stimulus and configuration unconsciously affects the viewer’s sense of familiarity.

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Active Locomotion Increases Peak Firing Rates of Anterodorsal Thalamic Head Direction Cells

Journal of Neurophysiology ◽

10.1152/jn.2001.86.2.692 ◽

2001 ◽

Vol 86 (2) ◽

pp. 692-702 ◽

Cited By ~ 28

Author(s):

Michaël B. Zugaro ◽

Eiichi Tabuchi ◽

Céline Fouquier ◽

Alain Berthoz ◽

Sidney I. Wiener

Keyword(s):

Visual Cues ◽

Head Direction ◽

Small Reservoir ◽

Motion Cues ◽

Preferred Direction ◽

State Dependent ◽

Command Signals ◽

Rats And Mice ◽

Foraging Task ◽

Self Motion

Head direction (HD) cells discharge selectively in macaques, rats, and mice when they orient their head in a specific (“preferred”) direction. Preferred directions are influenced by visual cues as well as idiothetic self-motion cues derived from vestibular, proprioceptive, motor efferent copy, and command signals. To distinguish the relative importance of active locomotor signals, we compared HD cell response properties in 49 anterodorsal thalamic HD cells of six male Long-Evans rats during active displacements in a foraging task as well as during passive rotations. Since thalamic HD cells typically stop firing if the animals are tightly restrained, the rats were trained to remain immobile while drinking water distributed at intervals from a small reservoir at the center of a rotatable platform. The platform was rotated in a clockwise/counterclockwise oscillation to record directional responses in the stationary animals while the surrounding environmental cues remained stable. The peak rate of directional firing decreased by 27% on average during passive rotations ( r 2 = 0.73, P< 0.001). Individual cells recorded in sequential sessions ( n = 8) reliably showed comparable reductions in peak firing, but simultaneously recorded cells did not necessarily produce identical responses. All of the HD cells maintained the same preferred directions during passive rotations. These results are consistent with the hypothesis that the level of locomotor activity provides a state-dependent modulation of the response magnitude of AD HD cells. This could result from diffusely projecting neuromodulatory systems associated with motor state.

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Reduced left visual field bias for faces in adolescents with social anxiety disorder

Cognitive Neuropsychiatry ◽

10.1080/13546805.2020.1832456 ◽

2020 ◽

Vol 25 (6) ◽

pp. 421-434

Author(s):

Emilie Bäcklin Löwenberg ◽

Frida Aili ◽

Eva Serlachius ◽

Jens Högström ◽

Johan Lundin Kleberg

Keyword(s):

Anxiety Disorder ◽

Visual Field ◽

Social Anxiety ◽

Social Anxiety Disorder ◽

Left Visual Field ◽

Field Bias

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Equal Degrees of Object Selectivity for Upper and Lower Visual Field Stimuli

Journal of Neurophysiology ◽

10.1152/jn.00462.2010 ◽

2010 ◽

Vol 104 (4) ◽

pp. 2075-2081 ◽

Cited By ~ 16

Author(s):

Lars Strother ◽

Adrian Aldcroft ◽

Cheryl Lavell ◽

Tutis Vilis

Keyword(s):

Visual Field ◽

Occipital Cortex ◽

Recognition System ◽

Blood Oxygen Level Dependent ◽

Lower Visual Field ◽

Blood Oxygen Level ◽

Visual Areas ◽

Bold Responses ◽

Cortical Regions ◽

Lateral Occipital Cortex

Functional MRI (fMRI) studies of the human object recognition system commonly identify object-selective cortical regions by comparing blood oxygen level–dependent (BOLD) responses to objects versus those to scrambled objects. Object selectivity distinguishes human lateral occipital cortex (LO) from earlier visual areas. Recent studies suggest that, in addition to being object selective, LO is retinotopically organized; LO represents both object and location information. Although LO responses to objects have been shown to depend on location, it is not known whether responses to scrambled objects vary similarly. This is important because it would suggest that the degree of object selectivity in LO does not vary with retinal stimulus position. We used a conventional functional localizer to identify human visual area LO by comparing BOLD responses to objects versus scrambled objects presented to either the upper (UVF) or lower (LVF) visual field. In agreement with recent findings, we found evidence of position-dependent responses to objects. However, we observed the same degree of position dependence for scrambled objects and thus object selectivity did not differ for UVF and LVF stimuli. We conclude that, in terms of BOLD response, LO discriminates objects from non-objects equally well in either visual field location, despite stronger responses to objects in the LVF.

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First order connections of the visual sector of the thalamic reticular nucleus in marmoset monkeys (Callithrix jacchus)

Visual Neuroscience ◽

10.1017/s0952523807070770 ◽

2007 ◽

Vol 24 (6) ◽

pp. 857-874 ◽

Cited By ~ 11

Author(s):

THOMAS FITZGIBBON ◽

BRETT A. SZMAJDA ◽

PAUL R. MARTIN

Keyword(s):

Visual Field ◽

Callithrix Jacchus ◽

Higher Order ◽

Dorsal Lateral Geniculate Nucleus ◽

Thalamic Reticular Nucleus ◽

Reticular Nucleus ◽

Lower Visual Field ◽

First Order ◽

Cortical Areas ◽

Visual Areas

The thalamic reticular nucleus (TRN) supplies an important inhibitory input to the dorsal thalamus. Previous studies in non-primate mammals have suggested that the visual sector of the TRN has a lateral division, which has connections with first-order (primary) sensory thalamic and cortical areas, and a medial division, which has connections with higher-order (association) thalamic and cortical areas. However, the question whether the primate TRN is segregated in the same manner is controversial. Here, we investigated the connections of the TRN in a New World primate, the marmoset (Callithrix jacchus). The topography of labeled cells and terminals was analyzed following iontophoretic injections of tracers into the primary visual cortex (V1) or the dorsal lateral geniculate nucleus (LGNd). The results show that rostroventral TRN, adjacent to the LGNd, is primarily connected with primary visual areas, while the most caudal parts of the TRN are associated with higher order visual thalamic areas. A small region of the TRN near the caudal pole of the LGNd (foveal representation) contains connections where first (lateral TRN) and higher order visual areas (medial TRN) overlap. Reciprocal connections between LGNd and TRN are topographically organized, so that a series of rostrocaudal injections within the LGNd labeled cells and terminals in the TRN in a pattern shaped like rostrocaudal overlapping “fish scales.” We propose that the dorsal areas of the TRN, adjacent to the top of the LGNd, represent the lower visual field (connected with medial LGNd), and the more ventral parts of the TRN contain a map representing the upper visual field (connected with lateral LGNd).

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